380 likes | 552 Views
Chapter 6. Momentum and Collisions. Momentum. The linear momentum of an object of mass m moving with a velocity is defined as the product of the mass and the velocity SI Units are kg m / s Vector quantity, the direction of the momentum is the same as the velocity’s. Momentum components.
E N D
Chapter 6 Momentum and Collisions
Momentum • The linear momentum of an object of mass m moving with a velocity is defined as the product of the mass and the velocity • SI Units are kg m / s • Vector quantity, the direction of the momentum is the same as the velocity’s
Momentum components • Applies to two-dimensional motion
Impulse • In order to change the momentum of an object, a force must be applied • The time rate of change of momentum of an object is equal to the net force acting on it • Gives an alternative statement of Newton’s second law
Impulse cont. • When a single, constant force acts on the object, there is an impulse delivered to the object • is defined as the impulse • Vector quantity, the direction is the same as the direction of the force
Impulse-Momentum Theorem • The theorem states that the impulse acting on the object is equal to the change in momentum of the object • If the force is not constant, use the average force applied
Average Force in Impulse • The average force can be thought of as the constant force that would give the same impulse to the object in the time interval as the actual time-varying force gives in the interval
Average Force cont. • The impulse imparted by a force during the time interval Δt is equal to the area under the force-time graph from the beginning to the end of the time interval • Or, the impulse is equal to the average force multiplied by the time interval,
Impulse Applied to Auto Collisions • The most important factor is the collision time or the time it takes the person to come to a rest • This will reduce the chance of dying in a car crash • Ways to increase the time • Seat belts • Air bags
Air Bags • The air bag increases the time of the collision • It will also absorb some of the energy from the body • It will spread out the area of contact • decreases the pressure • helps prevent penetration wounds
Conservation of Momentum • Momentum in an isolated system in which a collision occurs is conserved • A collision may be the result of physical contact between two objects • “Contact” may also arise from the electrostatic interactions of the electrons in the surface atoms of the bodies • An isolated system will have not external forces
Conservation of Momentum, cont • The principle of conservation of momentum states when no external forces act on a system consisting of two objects that collide with each other, the total momentum of the system remains constant in time • Specifically, the total momentum before the collision will equal the total momentum after the collision
Conservation of Momentum, cont. • Mathematically: • Momentum is conserved for the system of objects • The system includes all the objects interacting with each other • Assumes only internal forces are acting during the collision • Can be generalized to any number of objects
Notes About A System • Remember conservation of momentum applies to the system • You must define the isolated system
Types of Collisions • Momentum is conserved in any collision • Inelastic collisions • Kinetic energy is not conserved • Some of the kinetic energy is converted into other types of energy such as heat, sound, work to permanently deform an object • Perfectly inelastic collisions occur when the objects stick together • Not all of the KE is necessarily lost
More Types of Collisions • Elastic collision • both momentum and kinetic energy are conserved • Actual collisions • Most collisions fall between elastic and perfectly inelastic collisions
More About Perfectly Inelastic Collisions • When two objects stick together after the collision, they have undergone a perfectly inelastic collision • Conservation of momentum becomes
Some General Notes About Collisions • Momentum is a vector quantity • Direction is important • Be sure to have the correct signs
More About Elastic Collisions • Both momentum and kinetic energy are conserved • Typically have two unknowns • Solve the equations simultaneously
Elastic Collisions, cont. • A simpler equation can be used in place of the KE equation
Summary of Types of Collisions • In an elastic collision, both momentum and kinetic energy are conserved • In an inelastic collision, momentum is conserved but kinetic energy is not • In a perfectly inelastic collision, momentum is conserved, kinetic energy is not, and the two objects stick together after the collision, so their final velocities are the same
Problem Solving for One -Dimensional Collisions • Coordinates: Set up a coordinate axis and define the velocities with respect to this axis • It is convenient to make your axis coincide with one of the initial velocities • Diagram: In your sketch, draw all the velocity vectors and label the velocities and the masses
Problem Solving for One -Dimensional Collisions, 2 • Conservation of Momentum: Write a general expression for the total momentum of the system before and after the collision • Equate the two total momentum expressions • Fill in the known values
Problem Solving for One -Dimensional Collisions, 3 • Conservation of Energy: If the collision is elastic, write a second equation for conservation of KE, or the alternative equation • This only applies to perfectly elastic collisions • Solve: the resulting equations simultaneously
Sketches for Collision Problems • Draw “before” and “after” sketches • Label each object • include the direction of velocity • keep track of subscripts
Sketches for Perfectly Inelastic Collisions • The objects stick together • Include all the velocity directions • The “after” collision combines the masses
Glancing Collisions • For a general collision of two objects in three-dimensional space, the conservation of momentum principle implies that the total momentum of the system in each direction is conserved • Use subscripts for identifying the object, initial and final velocities, and components
Glancing Collisions • The “after” velocities have x and y components • Momentum is conserved in the x direction and in the y direction • Apply conservation of momentum separately to each direction
Problem Solving for Two-Dimensional Collisions • Coordinates: Set up coordinate axes and define your velocities with respect to these axes • It is convenient to choose the x- or y- axis to coincide with one of the initial velocities • Draw: In your sketch, draw and label all the velocities and masses
Problem Solving for Two-Dimensional Collisions, 2 • Conservation of Momentum: Write expressions for the x and y components of the momentum of each object before and after the collision • Write expressions for the total momentum before and after the collision in the x-direction and in the y-direction
Problem Solving for Two-Dimensional Collisions, 3 • Conservation of Energy: If the collision is elastic, write an expression for the total energy before and after the collision • Equate the two expressions • Fill in the known values • Solve the quadratic equations • Can’t be simplified
Problem Solving for Two-Dimensional Collisions, 4 • Solve for the unknown quantities • Solve the equations simultaneously • There will be two equations for inelastic collisions • There will be three equations for elastic collisions
Rocket Propulsion • The operation of a rocket depends on the law of conservation of momentum as applied to a system, where the system is the rocket plus its ejected fuel • This is different than propulsion on the earth where two objects exert forces on each other • road on car • train on track
Rocket Propulsion, 2 • The rocket is accelerated as a result of the thrust of the exhaust gases • This represents the inverse of an inelastic collision • Momentum is conserved • Kinetic Energy is increased (at the expense of the stored energy of the rocket fuel)
Rocket Propulsion, 3 • The initial mass of the rocket is M + Δm • M is the mass of the rocket • m is the mass of the fuel • The initial velocity of the rocket is
Rocket Propulsion • The rocket’s mass is M • The mass of the fuel, Δm, has been ejected • The rocket’s speed has increased to
Rocket Propulsion, final • The basic equation for rocket propulsion is: • Mi is the initial mass of the rocket plus fuel • Mf is the final mass of the rocket plus any remaining fuel • The speed of the rocket is proportional to the exhaust speed
Thrust of a Rocket • The thrust is the force exerted on the rocket by the ejected exhaust gases • The instantaneous thrust is given by • The thrust increases as the exhaust speed increases and as the burn rate (ΔM/Δt) increases